JP2013160771A - Device for detecting and synchronizing position of wheel of clock mechanism - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a small-sized device for detecting and synchronizing the position of a wheel of a clock mechanism.SOLUTION: In the device for detecting and synchronizing the position of at least one first wheel 16 of a clock mechanism for an electronic watch with hands, the first wheel 16 extends in one plane P1. The device comprises at least one light source 32a emitting a light beam and at least one light detection system. In the device, a first light reflective member 40 protrudes from one of upper and lower surfaces of the first wheel 16 of the clock mechanism, and the light source 32a and the light detection system are arranged such that, in a specific position of the first wheel 16 of the clock mechanism, the light beam emitted by the light source 32a is reflected towards the light detection system by the first reflective member 40.

Description

  The present invention relates to a device for detecting and synchronizing the position of a wheel of a timepiece mechanism of an electric analog timepiece. More particularly, the invention relates to such a detection and synchronization device comprising a light source and a light detection system.

  2. Description of the Related Art An electric analog timepiece is known in which an hour hand and a minute hand for displaying the current time are driven by the same motor or separate motors, and a wheel of a timepiece mechanism is advanced stepwise by this motor. In either case, the motor step can be missed by the impact the watch experiences, the presence of an electromagnetic field, or other external interference. As a result, even though the watch's internal clock conveys the correct indication of the current time, the motor has skipped several steps due to the external interference that the watch suffers. Tells the current time with an incorrect display. Therefore, it is necessary to synchronize the positions of the hour hand and the minute hand again, and this resynchronization is activated by application software or by the user.

  In order to be able to perform this synchronization, the timepiece is equipped with a device for detecting the positions of the hour wheel and the second wheel. At a predetermined time or when activated by the user, the control circuit issues a command to advance the hour wheel and second wheel. This control needs to be performed sequentially, that is, for one wheel followed by the next wheel. During the travel of the forward movement, the hour wheel and the second wheel pass through a predetermined position where a device for detecting the position is activated, so that the positions of the hour wheel and the second wheel can be accurately known. . The control circuit then calculates the wheel position and compares it with the value supplied from the internal clock of the watch, and moves the hands to display the current time to the appropriate position on the watch dial. In order to achieve this, the number of motor steps that must be applied to the hour and minute hands is subtracted from these operations.

  A known solution for detecting the position of the wheel of a timepiece mechanism of an electric analog timepiece consists of providing a light source emitting light and a light detection system provided on both sides of the wheel disk. The light source and the light detection system are arranged so as to face each other, and a hole is provided in the disk of the wheel on the passage between the light source and the light detection system. When the hole reaches the height of the light source, the light beam passes through the hole and strikes the light detection system, which can provide an accurate indication of the position of the wheel.

  Such a device for detecting and synchronizing the position of the wheel of the clock mechanism of an electric analog timepiece has several drawbacks. In fact, the first of these drawbacks is that the light source and the light detection system are arranged in essentially vertical steps, which makes the detection and synchronization device bulky and necessitates space above and below Will occur. The second problem occurs decisively when it is necessary to detect the positions of the two wheels installed coaxially, as in the case of the hour wheel and the second wheel. In fact, in such a situation, for example, it is necessary to place two light detection devices between the two wheels and position the light sources at the top and bottom of the two coaxial wheel assemblies, respectively. Such an arrangement is not only bulky, but also requires two additional elements of the detection device, such as two light detection devices, and automation of the production of such a watch movement is practically impossible. It is.

  The object of the present invention is to overcome the above and other disadvantages by providing a device for detecting and synchronizing the position of the wheel of the watch mechanism, in particular of a smaller size.

  Based on this, the present invention relates to a device for detecting and synchronizing the position of at least one first wheel of a timepiece mechanism of an electric analog timepiece, the first wheel extending in one plane. The detection and synchronization device comprises at least one light source that emits light and at least one light detection system, wherein the first light reflecting element is a top surface of the first wheel of the timepiece mechanism or Projecting from one of the lower surfaces, the light source and the light detection system, at a predetermined position on the first wheel of the timepiece mechanism, the light emitted by the light source is reflected by the first light reflecting element in the direction of the light detection system. It is characterized by being arranged.

  Due to these features, the present invention provides a detection and synchronization device in which the light rays emitted by the light source are reflected in the direction of the light detection system by a reflective element on the surface of the watch mechanism wheel. Instead of being arranged on either side of the wheel, the light source and detection system can be arranged on the periphery of the wheel, which can substantially increase the space.

  According to a supplementary feature of the invention, the light source emits light in a direction parallel to the plane in which the wheel of the watch mechanism extends.

  Instead of hitting the wheel surface perpendicularly, the light emitted by the light source diffuses parallel to the plane in which the wheel extends. Therefore, the light source and the light detection system are arranged in the same plane as the plane in which the wheel of the timepiece mechanism extends or in a plane parallel to the plane. Thus, the detection device according to the invention extends in the parallel direction rather than in the vertical direction, so that the thickness of the watch mechanism can be substantially reduced and the space already present around the wheel is not required. Can be used to house elements. Thus, the timepiece mechanism can be equipped with the detection and synchronization device according to the invention without changing the dimensions.

  According to a variant of the invention, the timepiece mechanism comprises two wheels arranged coaxially instead of one wheel, the second wheel extending in a plane parallel to the plane in which the first wheel extends. Exists. Similar to the first wheel, the second wheel comprises a light reflecting element protruding from one of its upper or lower surfaces, which light ray emitted by the light source at a predetermined position of the second wheel. Reflect in the direction of the light detection system.

  Since the light source and the light detection system are arranged at the periphery of a two-wheel assembly mounted coaxially, it is not necessary to position the elements of the detection and synchronization device between these wheels, thereby The manufacturing process can be automated. In addition, the structure of the detection and synchronization system according to the present invention is significantly simplified because the positions of the first and second wheels can be sequentially detected using the same light source and the same light detection system alternately. Therefore, reliability can be improved.

  Other features and advantages of the present invention will become more apparent from the following detailed description of exemplary embodiments of the detection device according to the present invention, which examples are given purely in conjunction with the accompanying drawings. Listed for non-limiting and illustrative purposes.

FIG. 1 is a plan view of a timepiece mechanism comprising a device for detecting and synchronizing the position of a wheel according to the present invention. FIG. 2 is a cross-sectional view of the timepiece mechanism of FIG. 1 taken along line AA. FIG. 3 is a view similar to FIG. 2 of a variation of the detection and synchronization device according to the present invention.

  The present invention is derived from the general inventive idea of being equipped with a watch mechanism wheel, where the position of the wheel can be detected using a reflective element, The light beam emitted from the light source disposed on the wheel periphery and similarly disposed on the wheel periphery can be similarly reflected in the direction of the light detection system disposed on the wheel periphery. Therefore, instead of placing the light source and the light detection system in steps on either side of the wheel disk (which is bulky and increases the thickness of the watch mechanism), the space already present around the wheel is It can be used to accommodate these two components. As a result, an electrical analog timepiece can be equipped with the detection and synchronization device according to the present invention without changing its dimensions. Furthermore, if it is desired to detect the position of two coaxially mounted wheels, it is not necessary to house some of the components of the detection and synchronization device between the two wheels, which increases the thickness of the watch This means that it is not necessary and automatic assembly of the clock mechanism is possible. Moreover, a single light source and a single detection system are sufficient to detect the position of the two wheels sequentially. Therefore, the structure of the detection and synchronization system according to the present invention is significantly simplified and its operation is more reliable.

  FIG. 1 is a plan view of a timepiece mechanism equipped with a device for detecting and synchronizing the position of a wheel according to the present invention. FIG. 2 is a cross-sectional view of the timepiece mechanism of FIG. 1 taken along line AA.

  A timepiece mechanism for attaching to an electric analog timepiece, denoted by 1 throughout, comprises a first electric motor 2, which in a known manner is a gear 6 comprising a wheel 8 and a pinion 10. Is used to drive the center wheel & pinion 4. According to an arrangement which is known per se and which is not described here, the center wheel & pinion 4 is firmly connected to the minute hand 12. Similarly, the timepiece mechanism 1 includes a second electric motor 14, which drives the hour wheel 16 using a gear 18 including a wheel 20 and a pinion 22. The hour wheel 16 is firmly connected to the hour hand 24. This is also a method known per se, and the hour wheel 16 and the center wheel & pinion 4 are installed coaxially so as to be separated from each other in the vertical direction. The hour wheel 16 is installed on a wheel 26 that moves the hour hand, and the center wheel 4 is installed on a cylindrical pinion 28 that is concentric with the wheel 26 that moves the hour hand.

  The timepiece mechanism 1 also includes a device 30 for detecting and synchronizing the positions of the hour wheel 16 and the center wheel & pinion 4. According to the invention, this device 30 for detecting and synchronizing the position of the wheel comprises a light source 32 that emits a light beam 34 represented in bold in the figure. As will be seen in detail below, the light beam 34 emitted by the light source 32 returns to the direction of the light detection system 36 after reflection. Advantageously, both the light source 32 and the light detection system 36 are mounted on the same printed circuit board 38, which is the installation of the other components of the watch mechanism 1, including in particular the electric motors 2 and 14. Also used for.

  According to the present invention, light reflecting elements 40 and 42 are attached to the hour wheel 16 and the center wheel & pinion 4 respectively, and these protrude from the upper surface or the lower surface of the wheel to which they are connected, respectively.

  According to a preferred, non-limiting embodiment of the invention, the reflective elements 40 and 42 are each provided in the form of tabs that extend at an essentially 90 ° angle to the wheel disk. More precisely, the tab or reflecting element 40 protrudes from the inner surface of the hour wheel 16 and the tab or reflecting element 42 protrudes from the upper surface of the center wheel 4.

  Furthermore, according to the present invention, the light source 32 and the light detection system 36 are arranged so that the light beam 34 is reflected by the tab 40 of the hour wheel 16 toward the light detection system 36 at a clearly defined position of the hour wheel 16. Set up. When this reflection occurs, the position of the hour wheel 16 is accurately known, and the electric motor 14 must be advanced by several steps in order to use the hour wheel 16 to move the hour hand to the appropriate position on the watch dial. I understand.

  Similarly, the light source 32 and the light detection system 36 are arranged so that the light beam 34 is reflected by the tab 42 of the second wheel 4 toward the light detection system 36 at a well-defined position of the second wheel 4. Set up. Then, it is understood how many steps the electric motor 2 must be advanced in order to move the minute hand to a desired position on the dial of the timepiece using the second wheel & pinion 4.

  In order to allow the light beam 34 emitted from the light source 32 to be reflected alternately by the tab 40 of the hour wheel 16 and the tab 42 of the center wheel & pinion 4, these two tabs are not arranged on the extension of each other. Otherwise one tab will be shielded by the other tab during measurement. Thus, a single light source and a single light detection system are sufficient to sequentially detect the position of the two wheels and their respective needle positions. The synchronization of the two needles must be done sequentially, ie for one needle followed by the next needle. For further details of the needle synchronization process, see pages 107-109 of the 2007 International Congress of Chronometry Minutes (issued by Swiss Chronometry Society). The optical detection device according to the invention can be calibrated in the same way as the LC oscillator described in this document, the frequency of which varies depending on the proximity of the metal of interest. Thus, when operating the watch or during battery replacement, the control circuit rotates each hand equipped with the optical detection device according to the present invention one turn, thereby responding using the maximum point of light reflection by the tab. Determine the placement of the wheel tabs. One rotation of the hand that goes around the dial requires, for example, 180 motor steps. The intensity of light detected by the light detection system is measured after each motor step. When passing through a wheel tab facing the light detection system, the intensity of the light reflected by the tab increases sharply. This steep rise in the measured light intensity indicates the detection of the wheel tab position. And the position corresponding to the steep rise of the detected light is memorize | stored in memory. When the watch maneuver program or the user initiates synchronization, the control circuit performs N counter-clockwise motor steps starting from the position corresponding to the steep rise in reflected light intensity, and the wheel tab is Prior to the position facing the light detection system, no measurement for positioning is performed. The control system then performs 2N motor steps with measurements at each step. The 2N value obtained in this way is stored in the memory. Then, the control circuit calculates the position of the hand, compares it with the value supplied from the internal clock of the timepiece, and corrects it by resetting the motor pulse if necessary.

  On the other hand, the two tabs 40 and 42 are substantially vertical between the hour wheel 16 and the second wheel 4 on the median plane P parallel to the planes P1 and P2 from which the hour wheel 16 and the second wheel 4 extend, respectively. It should be understood that the tab or reflecting element 40 protrudes from the lower surface of the hour wheel 16 and the tab or reflecting element 42 protrudes from the upper surface of the center wheel 4.

  Thus, according to the present invention, the position of the two wheels 16 and 4 can be detected using a single detection and synchronization device 30 comprising a single light source 32 and a single light detection system 36. . Therefore, the detection and synchronization device 30 according to the present invention has higher reliability. In addition, the light source 32 and the light detection system 36 are arranged at the periphery of the wheels 16 and 4 so that the space already present around the two wheels 16 and 4 can be accommodated for these two components. Can be used. For this reason, the dimensions of the watch mechanism 1 equipped with the detection and synchronization device 30 according to the invention remain unchanged. Moreover, in contrast to the prior art, it is not necessary to house the components of the detection and synchronization device 30 between the two wheels 16 and 4 within the framework of the present invention. Therefore, the timepiece mechanism manufactured as a result is not thick and can be manufactured automatically.

  According to a first variant of the invention shown in FIG. 2, the light source 32 is a known laser diode, called a vertical cavity surface emitting laser or VCSEL. Thanks to this design, the laser diode 32a emits a light beam 34a in a direction perpendicular to the median plane P on which the hour wheel 16 and the center wheel & pinion 4 extend. Therefore, it is necessary to return the light ray 34a in a direction parallel to the median plane P in which the reflecting elements 40 and 42 extend. For this purpose, an optical device 44a is provided, which comprises three polarizers 46, 48 and 50 arranged at 45.degree. With respect to the direction of diffusion of the light beam 34a. The light ray 34a can be sequentially deflected by 90 ° so that it is incident on the light, so that it can be reflected by one or the other of the reflective elements 40 or 42. In addition, the optical device 44a deflects the light beam 34a in the direction of the reflective elements 40 and 42 and directs the light reflected by these reflective elements 40 and 42 to the light detection system 36. Arranged.

  According to a second variant of the invention shown in FIG. 3, the light source 32 is a light emitting diode or LED. The advantage of such a light emitting diode 32b is that it can be oriented to emit light rays 34b directly or in a direction parallel to the median plane P. In contrast to the laser diode, the light emitting diode 32b emits a further branched beam 34b. As a result, an optical device 44b is provided that is arranged to focus the light beam 34b in the direction of the reflective elements 40 and 42 and concentrate the light reflected by these reflective elements 40 and 42 onto the light detection system 36. .

  The present invention is not limited to the embodiments described above, and various simple modifications and variations can be envisaged by those skilled in the art without departing from the scope of the present invention as defined in the appended claims. Is understood. In particular, it is not necessary to arrange the light source and the light detection system on the same plane. In fact, it is equally possible to arrange the light source and the light detection system on the periphery of the wheel in different planes, depending on the direction in which the reflective elements of the watch mechanism wheel reflect light. If the hour wheel 16 and the center wheel & pinion 42 are made of metal, the tabs or reflective elements 40 and 42 can be cut from the discs of these wheels 16 and 4. If the hour wheel 16 and the center wheel & pinion 42 are made of a plastic material, the tabs or reflecting elements 40 and 42 can be a single part with these wheels 4 and 16. Further, the tabs 40 and 42 can be plated in order to improve the reflectance of the incident light beam.

  According to an interesting variant of the invention, the light detection system 36 is a matrix sensor, which can be used to electrically distinguish which of the two wheels 16, 4 is the current detection object. In fact, the light hits different areas of the matrix sensor due to the difference in the distance that the rays reflected by the tab 40 of the hour wheel 16 and the tab 42 of the center wheel 4 can reach. The light detection system 36 can also be a photoelectric detector such as a photodiode.

Claims (14)

A device (30) for detecting and synchronizing the position of at least one first wheel (16) of a clock mechanism (1) of an electric analog timepiece,
The first wheel (16) extends in one plane (P1) and the detection and synchronization device (30) comprises at least one light source (32) emitting at least one light beam (34) and at least one Comprising a light detection system (36),
The first light reflecting element (40) protrudes from one of the upper surface and the lower surface of the first wheel (16) of the timepiece mechanism (1), and the light source (32) and the light detection system (36). ) At a predetermined position of the first wheel (16) of the timepiece mechanism (1), the light beam (34) emitted by the light source (32) is caused by the first light reflecting element (40). A detection and synchronization device (30), characterized in that it is arranged to be reflected in the direction of the light detection system (36).   The light source (32) emits the light beam (34) in a direction parallel to the plane (P1) in which the first wheel (16) of the timepiece mechanism (1) extends, The detection and synchronization device (30) according to claim 1.   Detection and synchronization device (30) according to any one of claims 1 and 2, characterized in that the first reflective element (40) is provided in the form of a tab.   4. The tab according to claim 3, characterized in that the tab is bent at an angle of 90 [deg.] With respect to the plane (P1) from which the first wheel (16) of the timepiece mechanism (1) extends. The described detection and synchronization device (30). 5. The method according to claim 3, wherein the first wheel is made of metal, and the tab is cut from a disk of the first wheel. The described detection and synchronization device (30). Either of the claims 3 and 4, characterized in that the first wheel (16) is made of a plastic material and that the tab is a single piece with the first wheel (16). The detection and synchronization device (30) according to claim 1.   The detection and synchronization device (30) according to claim 6, characterized in that the tab is plated in order to improve the reflectivity of the incident light beam (34).   The detection and synchronization device (30) according to any one of claims 1 to 7, characterized in that the light source (32) is a light emitting diode (32b).   The detection and synchronization device (30) is adapted to converge light rays (34b) emitted by the light emitting diode (32b) in the direction of the first reflective element (40) and to the first reflective element. Detection and synchronization according to claim 8, characterized in that it comprises an optical device (44b) arranged to concentrate the light reflected at (40) onto the light detection system (36). Device (30).   8. Detection and synchronization device (30) according to any one of the preceding claims, characterized in that the light source (32) is a vertical cavity surface emitting laser or a VCSEL type diode (32a). The laser diode (32a) emits a light beam (34a) in a direction perpendicular to the plane (P1) from which the first wheel (16) extends, and the detection and synchronization device (30) , An optical device (44a), wherein the optical device (44a) is arranged in a direction parallel to the plane (P1) in which the first wheel (16) of the timepiece mechanism (1) extends. Detection according to claim 10, characterized in that it is arranged for deflecting 34a) and for directing said light beam (34a) in the direction of said first reflective element (40). And a synchronization device (30). The second wheel (4) of the timepiece mechanism (1) is installed coaxially with the first wheel, wherein the second wheel (4) is extended by the first wheel (16). Extending in a plane parallel to the existing plane (P1),
The second wheel (4) comprises a second light reflecting element (42) protruding from one of the upper or lower surface of the second wheel (4), and the second wheel (4) The second reflective element (42) reflects the light beam (34) emitted by the light source (32) in the direction of the light detection system (36). 12. Detection and synchronization device (30) according to any one of the preceding claims. The first wheel (16) of the timepiece mechanism (1) supports an hour hand;
Said second wheel (4) supports the minute hand, and
13. Detection and synchronization device (30) according to claim 12, characterized in that the hour hand and the minute hand are driven by the same electric motor or by two separate electric motors (14, 2).   14. Detection and synchronization device (30) according to any one of the preceding claims, characterized in that the light detection system (36) is a matrix sensor or a photodiode.

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